تاثیر تنش کم آبی بر رشد و برخی ویژگی های فیزیولوژی درخت زینتی سرخدار (Taxus baccata L)
محورهای موضوعی : مجله گیاهان زینتی
فرنوش شاه محمدی
1
,
مرضیه قنبری جهرمی
2
,
محسن فرهادپور
3
,
سپیده کلاته جاری
4
,
علی محمدی ترکاشوند
5
1 - روه علوم باغبانی و زراعت، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران
2 - گروه علوم باغبانی و زراعت، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران
3 - گروه فرآورده های زیستی گیاهی، موسسه ملی مهندسی ژنتیک و بیوتکنولوژی (NIGEB)، تهران، ایران
4 - گروه علوم باغبانی و زراعت، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران
5 - گروه علوم باغبانی و زراعت، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران
کلید واژه: آنزیمهای آنتی اکسیدانی, سرخدار, تنش اسمزی, اسانس,
چکیده مقاله :
بهمنظور بررسی اثر تنش خشکی بر رشد و ویژگیهای بیوشیمیایی سرخدار تحقیقی در محیط گلخانه با 4 سطح تنش خشکی (100، 75، 50 و 25 درصد ظرفیت زراعی) در سه تکرار در قالب طرح کاملا تصادفی انجام شد. در این تحقیق که از نهال 3 ساله استفاده گردید نسبت وزن تر به خشک اندام هوایی و ریشه، کلروفیل a و b و نسبت این دو، محتوای نسبی آب برگ، فعالیت آنزیم سوپراکسید دیسموتاز و کاتالاز و درصد و عملکرد اسانس ارزیابی شد. نتایج نشان داد صفات رشدی و رنگیزه های فتوسنتزی و محتوای نسبی آب برگ با افزایش شدت تنش خشکی، کاهش پیدا کردند. البته فعالیت آنزیم های کاتالاز و سوپراکسید دیسموتاز با شدت تنش خشکی افزایش یافتند. بیشترین درصد اسانس در شرایط تنش خشکی نیمه شدید (50 درصد ظرفیت زراعی) حاصل شد. با افزایش میزان تنش خشکی تا 25 درصد ظرفیت زراعی درصد اسانس کاهش یافت. بیشتر شاخصهای رشد و فیزیولوژی گیاه سرخدار در سطح 75 درصد ظرفیت زراعی در مقایسه با 100 درصد ظرفیت زراعی تفاوت معنیدار نداشت بنابراین به نظر میرسد این گیاه در شرایط 75 درصد زراعی تحمل خوبی نشان دارد و از عملکرد قابل قبولی برخوردار است. از این رو توصیه می شود کشت و پرورش این گیاه ارزشمند در شرایط مساعد محیطی و آب کافی و نهایتا در شرایط تنش ملایم صورت گیرد.
Drought is the most important environmental stress, which is usually defined as an external factor that has adverse effects in plants. The endangered yew species is very important for human societies for medicinal and ornamental reasons. The roots and leaves of this plant produce biochemical compounds such as flavonoids, alkaloids and tannins that act as anti-inflammatory, anti-cancer, anti-bacterial and anti-viral. The present research investigated the effect of different levels of drought stress (100, 75, 50 and 25% of field capacity) on the growth and biochemical characteristics of the yew plant in a greenhouse environment in three replications in the form of a completely randomized design. In this research, which used 3-year-old seedlings, the fresh-to-dry weight ratio of shoots and roots, chlorophyll a and b and the ratio of these two, the relative content of leaf water, the activity of superoxide dismutase and catalase enzymes, and the percentage and yield of essential oil were evaluated. The results showed that the growth traits and photosynthetic pigments and the relative water content of the leaves decreased with the increase in the severity of drought stress. Of course, the activity of catalase and superoxide dismutase enzymes increased with the intensity of drought stress. The highest percentage of essential oil was obtained in semi-severe drought stress conditions (50% F.C). With the increase of drought stress up to 25% F.C, the percentage of essential oil decreased. Most of the growth and physiology parameters of yew plant at 75% FC compared to 100% FC were not significantly different, so it seems that this plant shows good tolerance in the condition of 75% FC and has an acceptable yield. Therefore, it is recommended to cultivate this valuable plant in favorable environmental conditions with sufficient water and/or with only in mild stress conditions.
Alavi S.J. Ahmadi K. Hosseini S.M. Tabari M. and Nouri Z. 2019. The response of English yew (Taxus baccata L.) to climate change in the Caspian Hyrcanian Mixed Forest ecoregion. Regional Environmental Change 19, 1495-1506.
Amiripour A. Jahromi M.G. Soori M.K. and mohammadi Torkashvand A. 2021. Changes in essential oil composition and fatty acid profile of coriander (Coriandrum sativum L.) leaves under salinity and foliar-applied silicon. Industrial Crops and Products 168, 113599.
Arnon A.N. 1967. Method of extraction of chlorophyll in the plants. Journal of Agronomy 23, 112-121.
Arpiwi N.L. Muksin I.K. and Nio S.A. 2023. Drought Stress Decreases Morphophysiological Characteristics of Pongamia pinnata (L.) Pierre a Biodiesel Tree. Pakistan Journal of Biological Sciences 26(9), 463-471.
Askary M. Behdani M.A. Parsa S. Mahmoodi S. Jamialahmadi M. 2018. Water stress and manure application affect the quantity and quality of essential oil of Thymus daenensis and Thymus vulgaris. Ind Crops Prod 111, 336-344.
Bidabadi S.S. VanderWeide J. and Sabbatini P. 2020. Exogenous melatonin improves glutathione content, redox state and increases essential oil production in two Salvia species under drought stress. Scientific Reports 10, 6883.
Billah M. Aktar S. Brestic M. Zivcak M. Khaldun A.B.M. Uddin M.S. Bagum S.A. Yang X. Skalicky M. and Mehari T.G. 2021. Progressive Genomic Approaches to Explore Drought- and Salt-Induced Oxidative Stress Responses in Plants under Changing Climate. Plants 10, 1910.
Chowdhury J. Karim M. Khaliq Q. and Ahmed A. 2017. Effect of drought stress on bio-chemical change and cell membrane stability of soybean genotypes. Bangladesh Journal of Agricultural Research 42, 475-485.
Denaxa N.K. Damvakaris T. and Roussos P.A. 2020. Antioxidant defense system in young olive plants against drought stress and mitigation of adverse effects through external application of alleviating products. Scientia Horticulturae 259, 108812.
El Sabagh A. Hossain A. Barutcular C. Gormus O. Ahmad Z. Hussain S. Islam M. Alharby H. Bamagoos A. Kumar N. Akdeniz H. Fahad S. Meena R.S. Abdelhamid M. Wasaya A. Hasanuzzaman M. Sorour S. and Saneoka H. 2019. Effects of drought stress on the quality of major oilseed crops: Implications and possible mitigation strategies—A review. Applied Ecology Environmental Research 17, 4019-4043.
Ghasemi Dehkordi, N. and Taleb A.M. 2018. Extraction, identification and determination of the amount of compounds in index medicinal plants. Sabze Arang Publications. 240 p.
Gholami R. Hoveizeh N.F. Zahedi S.M. Gholami H. Carillo P. 2022. Melatonin alleviates the adverse effects of water stress in adult olive cultivars (Olea europea cv. Sevillana & Roughani) in field condition. Agric Water Manag 269:107681.
Gholizadeh A. Dehghani H. and Khodadadi M. 2020. Analysis of compatibility for essential oil yield in coriander under different irrigation regimes using GGE biplot method. Iranian Journal of Field Crop Science 50(4), 189-199.
Giannopolitis C.N. and Ries S.K. 1977. Superoxide dismutases: I. Occurrence in higher plants. Plant physiology 59(2), 309-31.
Gurumurthy S. Sarkar B. Vanaja M. Lakshmi J. Yadav S. and Maheswari M. 2019. Morpho-physiological and biochemical changes in black gram (Vigna mungo L. Hepper) genotypes under drought stress at flowering stage. Acta Physiologia Plantarium 41, 42.
Hojjati M. Jahromi M.G. Abdossi V. and Torkashvand A.M. 2023. Exogenous Melatonin Modulated Drought Stress by Regulating Physio-Biochemical Attributes and Fatty acid Profile of Sweet Cherry (Prunus avium L.). J Plant Growth Regul 24, 1-5.
Hosseini M.S. Samsampour D. Zahedi S.M. Zamanian K. Rahman M.M. Mostofa M.G. and Tran L.S.P. 2021. Melatonin alleviates drought impact on growth and essential oil yield of lemon verbena by enhancing antioxidant responses, mineral balance, and abscisic acid content. Physiol Plant 172, 1363-1375.
Inbar J. Abramsky M. Cohen D. and Chet I. 1994. Plant growth enhancement and disease control by Trichoderma harzianum in vegetable seedlings grown under commercial conditions. European Journal of Plant Pathology 100(5), 337-346.
Jacomassi L.M. Viveiros J.O. Oliveira M.P. Momesso L. de Siqueira G.F. Crusciol C.A.C. 2022. A Seaweed Extract-Based Biostimulant Mitigates Drought Stress in Sugarcane. Frontiers in Plant Science 13, 865291.
Kapoor D. Bhardwaj S. Landi M. Sharma A. Ramakrishnan M. and Sharma A. 2020. The impact of drought in plant metabolism: how to exploit tolerance mechanisms to increase crop production. Applied Sciences 10, 56-92.
Luck H. 1965. Catalase. In: Bergmeyer, H.U., Ed., Method of Enzymatic Analysis, Academic Press, New York and London, 885-894.
Mahmud S. Kamruzzaman M. Bhattacharyya S. Alharbi K. Abd El Moneim D. and Mostofa M.G. 2023. Acetic acid positively modulates proline metabolism for mitigating PEG-mediated drought stress in Maize and Arabidopsis. Frontiers in Plant Science 14, 1167238.
Minaei A. Hassani A. Nazemiyeh H. and Besharat S. 2019. Effect of drought stress on some morphophysiological and phytochemical characteristics of oregano (Origanum vulgare L. ssp. gracile). Iranian Journal of Medicinal and Aromatic Plants Research 35(2), 252-265.
Oguz M.C. Aycan M. Oguz E. Poyraz I. and Yildiz M. 2022. Drought Stress Tolerance in Plants: Interplay of Molecular, Biochemical and Physiological Responses in Important Development Stages. Physiologia, 2 180-197.
Pamungkas S.S.T. Suwarto S. and Farid N. 2022. Drought Stress: Responses and Mechanism in Plants. Reviews in Agricultural Science, 10 168–185.
Ritchie S.W. Nguyan H.T. and Holaday A.S. 1990. Leaf Water content and gas exchange parameters of two wheat genotypes differing in drought resistance. Crop science 30, 105-111.
Shahmohammadi F. Ghanbari Jahromi M. Farhadpour, M. Kalateh Jari S. and Mohammadi Torkashvand A. 2023. Foliar-applied melatonin modulated drought stress through modifying some important physiological and phytochemical characteristics in Taxus baccata L. Plant and Soil, 1-16.
Shukla P.S. Shotton K. Norman E. Neily W. Critchley A.T. and Prithiviraj B. 2018. Seaweed extract improve drought tolerance of soybean by regulating stress-response genes. AoB Plants 10(1), plx051.
Soares C. Carvalho M.E. Azevedo R.A. and Fidalgo F. 2019. Plants facing oxidative challenges—A little help from the antioxidant networks. Environ Exp Bot 161, 4-25.
